Contrasting Changes in Diel Variations of Net Community Calcification Support That Carbonate Dissolution Can Be More Sensitive to Ocean Acidification Than Coral Calcification

Previous studies have found that calcification in coral reefs is generally stronger during the day, whereas dissolution is prevalent at night. On the basis of these contrasting patterns, the diel variations of net community calcification (NCC) were monitored to examine the relative sensitivity of Ca...

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Bibliographic Details
Published in:Frontiers in Marine Science 2020-01, Vol.7
Main Authors: Chou, Wen-Chen, Liu, Pi-Jen, Chen, Ying-Hsuan, Huang, Wei-Jen
Format: Article
Language:English
Subjects:
Accretion
Acidification
Calcification
Calcium carbonate
Carbon dioxide
carbonate dissolution
Carbonates
coral reef
Coral reef ecosystems
Coral reefs
diel variation
Diel variations
Dissolution
Dissolving
Experiments
Marine biology
mesocosm
Mesocosms
Museums
Ocean acidification
Saturation
Seawater
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Summary:Previous studies have found that calcification in coral reefs is generally stronger during the day, whereas dissolution is prevalent at night. On the basis of these contrasting patterns, the diel variations of net community calcification (NCC) were monitored to examine the relative sensitivity of CaCO3 production (calcification) and dissolution in coral reefs to ocean acidification (OA), using two mesocosms that replicated a typical subtropical coral reef ecosystem in southern Taiwan. The results revealed that the daytime NCC remained unchanged, whereas the nighttime NCC decreased between the control (ambient) and treatment (OA) conditions, suggesting that carbonate dissolution could be more sensitive to OA than coral calcification. The average sensitivity of the integrated daily NCC to changes in the seawater saturation state (a) was estimated to be a reduction of 54% in NCC per unit change in a, which is consistent with the global average. In summary, our results support the prevailing anticipation that OA would lead to a reduction in the overall accretion of coral reef ecosystems. However, increased CaCO3 dissolution rather than decreased coral calcification could be the dominant driving force responsible for this OA-induced reduction in NCC.
ISSN:2296-7745
2296-7745
DOI:10.3389/fmars.2020.00003